////////////////////////////////////////////////////////////////////////
//
// Copyright (C) 2003-2021 The Octave Project Developers
//
// See the file COPYRIGHT.md in the top-level directory of this
// distribution or <https://octave.org/copyright/>.
//
// This file is part of Octave.
//
// Octave is free software: you can redistribute it and/or modify it
// under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// Octave is distributed in the hope that it will be useful, but
// WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with Octave; see the file COPYING.  If not, see
// <https://www.gnu.org/licenses/>.
//
////////////////////////////////////////////////////////////////////////

#if defined (HAVE_CONFIG_H)
#  include "config.h"
#endif

#include <istream>
#include <list>
#include <ostream>
#include <sstream>
#include <string>
#include <vector>

#include "file-ops.h"
#include "oct-locbuf.h"

#include "defaults.h"
#include "defun.h"
#include "error.h"
#include "errwarn.h"
#include "file-stat.h"
#include "input.h"
#include "interpreter-private.h"
#include "interpreter.h"
#include "load-path.h"
#include "oct-env.h"
#include "oct-hdf5.h"
#include "oct-map.h"
#include "ov-base.h"
#include "ov-cell.h"
#include "ov-fcn-handle.h"
#include "ov-usr-fcn.h"
#include "parse.h"
#include "pr-output.h"
#include "pt-arg-list.h"
#include "pt-assign.h"
#include "pt-cmd.h"
#include "pt-eval.h"
#include "pt-exp.h"
#include "pt-idx.h"
#include "pt-misc.h"
#include "pt-pr-code.h"
#include "pt-stmt.h"
#include "stack-frame.h"
#include "syminfo.h"
#include "symscope.h"
#include "unwind-prot.h"
#include "variables.h"

#include "byte-swap.h"
#include "ls-ascii-helper.h"
#include "ls-hdf5.h"
#include "ls-oct-text.h"
#include "ls-oct-binary.h"
#include "ls-utils.h"


DEFINE_OV_TYPEID_FUNCTIONS_AND_DATA (octave_fcn_handle,
                                     "function handle",
                                     "function_handle");

const std::string octave_fcn_handle::anonymous ("@<anonymous>");

OCTAVE_NAMESPACE_BEGIN

  class invalid_fcn_handle : public base_fcn_handle
  {
  public:

    invalid_fcn_handle (void) : base_fcn_handle ("<invalid>") { }

    invalid_fcn_handle (const invalid_fcn_handle&) = default;

    ~invalid_fcn_handle (void) = default;

    invalid_fcn_handle * clone (void) const
    {
      return new invalid_fcn_handle (*this);
    }

    std::string type (void) const { return "<invalid>"; }

    octave_value_list call (int nargout, const octave_value_list& args);
  };

  // Create a handle to an unnamed internal function.  There will be no
  // way to save and reload it.  See, for example, the F__fltk_check__
  // function in __init_fltk__.cc.

  class internal_fcn_handle : public base_fcn_handle
  {
  public:

    internal_fcn_handle (const octave_value& fcn)
      : base_fcn_handle ("<internal>"), m_fcn (fcn)
    { }

    internal_fcn_handle (const internal_fcn_handle&) = default;

    ~internal_fcn_handle (void) = default;

    internal_fcn_handle * clone (void) const
    {
      return new internal_fcn_handle (*this);
    }

    std::string type (void) const { return "<internal>"; }

    bool is_internal (void) const { return true; }

    octave_value_list call (int nargout, const octave_value_list& args);

    // FIXME: These must go away.  They don't do the right thing for
    // scoping or overloads.
    octave_function * function_value (bool = false)
    {
      return m_fcn.function_value ();
    }

    octave_user_function * user_function_value (bool = false)
    {
      return m_fcn.user_function_value ();
    }

    octave_value fcn_val (void) { return m_fcn; }

    // Should be const.
    octave_scalar_map info (void);

    friend bool is_equal_to (const internal_fcn_handle& fh1,
                             const internal_fcn_handle& fh2);

  private:

    octave_value m_fcn;
  };

  class simple_fcn_handle : public base_fcn_handle
  {
  public:

    // FIXME: octaveroot is temporary information used when loading
    // handles.  Can we avoid using it in the constructor?

    simple_fcn_handle (const std::string& name = "",
                       const std::string& file = "",
                       const std::string& /*octaveroot*/ = "")
      : base_fcn_handle (name, file), m_fcn ()
    { }

    simple_fcn_handle (const octave_value& fcn, const std::string& name)
      : base_fcn_handle (name), m_fcn (fcn)
    {
      if (m_fcn.is_defined ())
        {
          octave_function *oct_fcn = m_fcn.function_value ();

          if (oct_fcn)
            m_file = oct_fcn->fcn_file_name ();
        }
    }

    simple_fcn_handle (const simple_fcn_handle&) = default;

    ~simple_fcn_handle (void) = default;

    simple_fcn_handle * clone (void) const
    {
      return new simple_fcn_handle (*this);
    }

    std::string type (void) const { return "simple"; }

    bool is_simple (void) const { return true; }

    octave_value_list call (int nargout, const octave_value_list& args);

    // FIXME: These must go away.  They don't do the right thing for
    // scoping or overloads.
    octave_function * function_value (bool);

    octave_user_function * user_function_value (bool);

    octave_value fcn_val (void);

    // Should be const.
    octave_scalar_map info (void);

    bool save_ascii (std::ostream& os);

    bool load_ascii (std::istream& is);

    bool save_binary (std::ostream& os, bool save_as_floats);

    bool load_binary (std::istream& is, bool swap, mach_info::float_format fmt);

    bool save_hdf5 (octave_hdf5_id loc_hid, const char *name, bool save_as_floats);

    bool load_hdf5 (octave_hdf5_id& group_hid, octave_hdf5_id& space_hid,
                    octave_hdf5_id& type_hid);

    void print_raw (std::ostream& os, bool pr_as_read_syntax,
                    int current_print_indent_level) const;

    friend bool is_equal_to (const simple_fcn_handle& fh1,
                             const simple_fcn_handle& fh2);

  private:

    octave_value m_fcn;
  };

  class scoped_fcn_handle : public base_fcn_handle
  {
  public:

    // FIXME: octaveroot is temporary information used when loading
    // handles.  Can we avoid using it in the constructor?

    scoped_fcn_handle (const std::string& name = "",
                       const std::string& file = "",
                       const std::string& /*octaveroot*/ = "")
      : base_fcn_handle (name, file)
    { }

    scoped_fcn_handle (const octave_value& fcn, const std::string& name,
                       const std::list<std::string>& parentage);

    scoped_fcn_handle (const scoped_fcn_handle&) = default;

    ~scoped_fcn_handle (void) = default;

    scoped_fcn_handle * clone (void) const
    {
      return new scoped_fcn_handle (*this);
    }

    std::string type (void) const { return "scopedfunction"; }

    bool is_scoped (void) const { return true; }

    octave_value_list call (int nargout, const octave_value_list& args);

    // FIXME: These must go away.  They don't do the right thing for
    // scoping or overloads.
    octave_function * function_value (bool = false)
    {
      return m_fcn.function_value ();
    }

    octave_user_function * user_function_value (bool = false)
    {
      return m_fcn.user_function_value ();
    }

    octave_value fcn_val (void) { return m_fcn; }

    // Should be const.
    octave_scalar_map info (void);

    bool save_ascii (std::ostream& os);

    bool load_ascii (std::istream& is);

    bool save_binary (std::ostream& os, bool save_as_floats);

    bool load_binary (std::istream& is, bool swap, mach_info::float_format fmt);

    bool save_hdf5 (octave_hdf5_id loc_id, const char *name, bool save_as_floats);

    bool load_hdf5 (octave_hdf5_id& group_hid, octave_hdf5_id& space_hid,
                    octave_hdf5_id& type_hid);

    void print_raw (std::ostream&, bool pr_as_read_syntax,
                    int current_print_indent_level) const;

    friend bool is_equal_to (const scoped_fcn_handle& fh1,
                             const scoped_fcn_handle& fh2);

  protected:

    void find_function (void);

    // The function we are handling.
    octave_value m_fcn;

    // List of parent function names.  The first element is the name of
    // m_fcn.
    std::list<std::string> m_parentage;
  };

  class base_nested_fcn_handle : public base_fcn_handle
  {
  public:

    // FIXME: octaveroot is temporary information used when loading
    // handles.  Can we avoid using it in the constructor?

    base_nested_fcn_handle (const std::string& name = "",
                            const std::string& file = "",
                            const std::string& /*octaveroot*/ = "")
      : base_fcn_handle (name, file)
    { }

    base_nested_fcn_handle (const octave_value& fcn, const std::string& name)
      : base_fcn_handle (name), m_fcn (fcn)
    { }

    std::string type (void) const { return "nested"; }

    using base_fcn_handle::is_nested;

    bool is_nested (void) const { return true; }

    // FIXME: These must go away.  They don't do the right thing for
    // scoping or overloads.
    octave_function * function_value (bool = false)
    {
      return m_fcn.function_value ();
    }

    octave_user_function * user_function_value (bool = false)
    {
      return m_fcn.user_function_value ();
    }

    octave_value fcn_val (void) { return m_fcn; }

    virtual octave_value workspace (void) const = 0;

    // Should be const.
    octave_scalar_map info (void);

    bool save_ascii (std::ostream& os);

    bool load_ascii (std::istream& is);

    bool save_binary (std::ostream& os, bool save_as_floats);

    bool load_binary (std::istream& is, bool swap, mach_info::float_format fmt);

    bool save_hdf5 (octave_hdf5_id loc_id, const char *name, bool save_as_floats);

    bool load_hdf5 (octave_hdf5_id& group_hid, octave_hdf5_id& space_hid,
                    octave_hdf5_id& type_hid);

    void print_raw (std::ostream&, bool pr_as_read_syntax,
                    int current_print_indent_level) const;

  protected:

    // The function we are handling.
    octave_value m_fcn;
  };

  class nested_fcn_handle : public base_nested_fcn_handle
  {
  public:

    // FIXME: octaveroot is temporary information used when loading
    // handles.  Can we avoid using it in the constructor?

    nested_fcn_handle (const std::string& name = "",
                       const std::string& file = "",
                       const std::string& octaveroot = "")
      : base_nested_fcn_handle (name, file, octaveroot)
    { }

    nested_fcn_handle (const octave_value& fcn, const std::string& name,
                       const std::shared_ptr<stack_frame>& stack_context)
      : base_nested_fcn_handle (fcn, name), m_stack_context (stack_context)
    {
      m_stack_context->mark_closure_context ();
    }

    nested_fcn_handle (const nested_fcn_handle&) = default;

    ~nested_fcn_handle (void) = default;

    using base_nested_fcn_handle::is_nested;

    bool is_nested (const std::shared_ptr<stack_frame>& frame) const
    {
      return frame == m_stack_context;
    }

    nested_fcn_handle * clone (void) const
    {
      return new nested_fcn_handle (*this);
    }

    octave_value make_weak_nested_handle (void) const;

    octave_value_list call (int nargout, const octave_value_list& args);

    octave_value workspace (void) const;

    friend bool is_equal_to (const nested_fcn_handle& fh1,
                             const nested_fcn_handle& fh2);

    std::shared_ptr<stack_frame> stack_context (void) const
    {
      return m_stack_context;
    }

  protected:

    // Pointer to closure stack frames.
    std::shared_ptr<stack_frame> m_stack_context;
  };

  class weak_nested_fcn_handle : public base_nested_fcn_handle
  {
  public:

    weak_nested_fcn_handle (const nested_fcn_handle& nfh)
      : base_nested_fcn_handle (nfh), m_stack_context (nfh.stack_context ())
    { }

    weak_nested_fcn_handle (const weak_nested_fcn_handle&) = default;

    ~weak_nested_fcn_handle (void) = default;

    weak_nested_fcn_handle * clone (void) const
    {
      return new weak_nested_fcn_handle (*this);
    }

    bool is_weak_nested (void) const { return true; }

    octave_value_list call (int nargout, const octave_value_list& args);

    octave_value workspace (void) const;

    friend bool is_equal_to (const weak_nested_fcn_handle& fh1,
                             const weak_nested_fcn_handle& fh2);

  protected:

    // Pointer to closure stack frames.
    std::weak_ptr<stack_frame> m_stack_context;
  };

  class class_simple_fcn_handle : public base_fcn_handle
  {
  public:

    // FIXME: octaveroot is temporary information used when loading
    // handles.  Can we avoid using it in the constructor?

    class_simple_fcn_handle (const std::string& name,
                             const std::string& file,
                             const std::string& /*octaveroot*/)
      : base_fcn_handle (name, file)
    { }

    // FIXME: is the method name supposed to be just the method name or
    // also contain the object name?

    class_simple_fcn_handle (const std::string& class_nm,
                             const std::string& meth_nm);

    class_simple_fcn_handle (const octave_value& fcn,
                             const std::string& class_nm,
                             const std::string& meth_nm);

    class_simple_fcn_handle (const octave_value& obj, const octave_value& fcn,
                             const std::string& class_nm,
                             const std::string& meth_nm);

    class_simple_fcn_handle (const class_simple_fcn_handle&) = default;

    ~class_simple_fcn_handle (void) = default;

    class_simple_fcn_handle * clone (void) const
    {
      return new class_simple_fcn_handle (*this);
    }

    std::string type (void) const { return "classsimple"; }

    bool is_class_simple (void) const { return true; }

    octave_value_list call (int nargout, const octave_value_list& args);

    // FIXME: These must go away.  They don't do the right thing for
    // scoping or overloads.
    octave_function * function_value (bool = false)
    {
      // FIXME: Shouldn't the lookup rules here match those used in the
      // call method?

      if (m_fcn.is_defined ())
        return m_fcn.function_value ();

      symbol_table& symtab
        = __get_symbol_table__ ("class_simple_fcn_handle::function_value");

      // FIXME: is caching the correct thing to do?
      // Cache this value so that the pointer will be valid as long as the
      // function handle object is valid.

      // FIXME: This should probably dispatch to the respective class method.
      // But that breaks if a function handle is used in a class method with
      // e.g. bsxfun with arguments of a different class (see bug #59661).
      // m_fcn = symtab.find_method (m_name, m_dispatch_class);
      m_fcn = symtab.find_function (m_name, octave_value_list ());

      return m_fcn.is_defined () ? m_fcn.function_value () : nullptr;
    }

    octave_user_function * user_function_value (bool = false)
    {
      return m_fcn.user_function_value ();
    }

    octave_value fcn_val (void) { return m_fcn; }

    // Should be const.
    octave_scalar_map info (void);

    std::string dispatch_class (void) const { return m_dispatch_class; }

    bool save_ascii (std::ostream& os);

    bool load_ascii (std::istream& is);

    bool save_binary (std::ostream& os, bool save_as_floats);

    bool load_binary (std::istream& is, bool swap, mach_info::float_format fmt);

    bool save_hdf5 (octave_hdf5_id loc_id, const char *name, bool save_as_floats);

    bool load_hdf5 (octave_hdf5_id& group_hid, octave_hdf5_id& space_hid,
                    octave_hdf5_id& type_hid);

    void print_raw (std::ostream&, bool pr_as_read_syntax,
                    int current_print_indent_level) const;

    friend bool is_equal_to (const class_simple_fcn_handle& fh1,
                             const class_simple_fcn_handle& fh2);

  protected:

    // The object containing the method we are handing.
    octave_value m_obj;

    // The method we are handling.
    octave_value m_fcn;

    // Name of the class that m_fcn belongs to.
    std::string m_dispatch_class;
  };

  // Handles to anonymous functions are similar to handles to nested
  // functions.  If they are created in a context that contains nested
  // functions, then they store a link to the parent call stack frames
  // that are active when they are created.  These call stack frames
  // (closure frames) provide access to variables needed by any nested
  // functions that are called from the anonymous function.  Anonymous
  // functions also store a list of values from their parent scope
  // corresponding to the symbols in the anonymous function.  This list
  // of values captures the variable values that are visible in the
  // scope where they are created.
  //
  // Note that because handles to anonymous and nested functions capture
  // call stack frames when they are created, they will cause deletion
  // of the values in those frames to be deferred until the handles to
  // the anonymous or nested functions are deleted.
  //
  // Would it be possible to avoid storing the closure frames for
  // handles to anonymous functions if we can determine that the
  // anonymous function has no unbound variables (or parameters, which
  // could be handles to nested functions?) or if it is not created in a
  // context that contains nested functions?
  //
  // Would it be possible to define anonymous functions as a special
  // type of nested function object that also has an variable
  // initialization list associated with it?

  class base_anonymous_fcn_handle : public base_fcn_handle
  {
  public:

    static const std::string anonymous;

    // Setting NAME here is a bit of a kluge to cope with a bad choice
    // made to append the number of local variables to the @<anonymous>
    // tag in the binary file format.  See also the save_binary and
    // load_binary functions.

    base_anonymous_fcn_handle (const std::string& name = "")
      : base_fcn_handle (name)
    { }

    base_anonymous_fcn_handle (const octave_value& fcn,
                               const stack_frame::local_vars_map& local_vars)
      : base_fcn_handle (anonymous), m_fcn (fcn), m_local_vars (local_vars)
    { }

    base_anonymous_fcn_handle (const base_anonymous_fcn_handle&) = default;

    ~base_anonymous_fcn_handle (void) = default;

    std::string type (void) const { return "anonymous"; }

    bool is_anonymous (void) const { return true; }

    // FIXME: These must go away.  They don't do the right thing for
    // scoping or overloads.
    octave_function * function_value (bool = false)
    {
      return m_fcn.function_value ();
    }

    octave_user_function * user_function_value (bool = false)
    {
      return m_fcn.user_function_value ();
    }

    octave_value fcn_val (void) { return m_fcn; }

    virtual octave_value workspace (void) const = 0;

    // Should be const.
    octave_scalar_map info (void);

    bool save_ascii (std::ostream& os);

    bool load_ascii (std::istream& is);

    bool save_binary (std::ostream& os, bool save_as_floats);

    bool load_binary (std::istream& is, bool swap, mach_info::float_format fmt);

    bool save_hdf5 (octave_hdf5_id loc_id, const char *name, bool save_as_floats);

    bool load_hdf5 (octave_hdf5_id& group_hid, octave_hdf5_id& space_hid,
                    octave_hdf5_id& type_hid);

    void print_raw (std::ostream&, bool pr_as_read_syntax,
                    int current_print_indent_level) const;

    // Anonymous function handles are printed without a newline.
    bool print_as_scalar (void) const { return false; }

    bool parse (const std::string& fcn_text);

  protected:

    // The function we are handling.
    octave_value m_fcn;

    // List of captured variable values for anonymous fucntions.
    stack_frame::local_vars_map m_local_vars;
  };

  class anonymous_fcn_handle : public base_anonymous_fcn_handle
  {
  public:

    using base_anonymous_fcn_handle::anonymous;

    // Setting NAME here is a bit of a kluge to cope with a bad choice
    // made to append the number of local variables to the @<anonymous>
    // tag in the binary file format.  See also the save_binary and
    // load_binary functions.

    anonymous_fcn_handle (const std::string& name = "")
      : base_anonymous_fcn_handle (name), m_stack_context ()
    { }

    anonymous_fcn_handle (const octave_value& fcn,
                          const stack_frame::local_vars_map& local_vars,
                          const std::shared_ptr<stack_frame>& stack_context = std::shared_ptr<stack_frame> ());

    anonymous_fcn_handle (const anonymous_fcn_handle&) = default;

    ~anonymous_fcn_handle (void) = default;

    anonymous_fcn_handle * clone (void) const
    {
      return new anonymous_fcn_handle (*this);
    }

    octave_value make_weak_anonymous_handle (void) const;

    octave_value_list call (int nargout, const octave_value_list& args);

    octave_value workspace (void) const;

    friend bool is_equal_to (const anonymous_fcn_handle& fh1,
                             const anonymous_fcn_handle& fh2);

    std::shared_ptr<stack_frame> stack_context (void) const
    {
      return m_stack_context;
    }

  protected:

    // Pointer to closure stack frames.
    std::shared_ptr<stack_frame> m_stack_context;
  };

  class weak_anonymous_fcn_handle : public base_anonymous_fcn_handle
  {
  public:

    using base_anonymous_fcn_handle::anonymous;

    weak_anonymous_fcn_handle (const anonymous_fcn_handle& afh)
      : base_anonymous_fcn_handle (afh), m_stack_context (afh.stack_context ())
    { }

    weak_anonymous_fcn_handle (const weak_anonymous_fcn_handle&) = default;

    ~weak_anonymous_fcn_handle (void) = default;

    weak_anonymous_fcn_handle * clone (void) const
    {
      return new weak_anonymous_fcn_handle (*this);
    }

    bool is_weak_anonymous (void) const { return true; }

    octave_value_list call (int nargout, const octave_value_list& args);

    octave_value workspace (void) const;

    friend bool is_equal_to (const weak_anonymous_fcn_handle& fh1,
                             const weak_anonymous_fcn_handle& fh2);

  protected:

    // Pointer to closure stack frames.
    std::weak_ptr<stack_frame> m_stack_context;
  };

  extern bool is_equal_to (const anonymous_fcn_handle& fh1,
                           const anonymous_fcn_handle& fh2);

  static void err_invalid_fcn_handle (const std::string& name)
  {
    error ("invalid function handle, unable to find function for @%s",
           name.c_str ());
  }

  octave_value base_fcn_handle::make_weak_nested_handle (void) const
  {
    std::string type_str = type ();
    error ("invalid conversion from %s handle to weak nestead handle",
           type_str.c_str ());
  }

  octave_value base_fcn_handle::make_weak_anonymous_handle (void) const
  {
    std::string type_str = type ();
    error ("invalid conversion from %s handle to weak anonymous handle",
           type_str.c_str ());
  }

  octave_value_list
  base_fcn_handle::subsref (const std::string& type,
                            const std::list<octave_value_list>& idx,
                            int nargout)
  {
    octave_value_list retval;

    switch (type[0])
      {
      case '(':
        {
          int tmp_nargout = (type.length () > 1 && nargout == 0) ? 1 : nargout;

          retval = call (tmp_nargout, idx.front ());
        }
        break;

      case '{':
      case '.':
        error ("function handle cannot be indexed with %c", type[0]);

      default:
        panic_impossible ();
      }

    // FIXME: perhaps there should be an
    // octave_value_list::next_subsref member function?  See also
    // octave_builtin::subsref.

    if (idx.size () > 1)
      retval = retval(0).next_subsref (nargout, type, idx);

    return retval;
  }

  octave_value
  base_fcn_handle::convert_to_str_internal (bool, bool, char type) const
  {
    std::ostringstream buf;
    print_raw (buf, true, 0);
    return octave_value (buf.str (), type);
  }

  bool
  base_fcn_handle::save_ascii (std::ostream&)
  {
    unimplemented ("save", "text");

    return true;
  }

  bool
  base_fcn_handle::load_ascii (std::istream&)
  {
    unimplemented ("load", "text");

    return true;
  }

  bool
  base_fcn_handle::save_binary (std::ostream&, bool)
  {
    unimplemented ("save", "binary");

    return true;
  }

  bool
  base_fcn_handle::load_binary (std::istream&, bool, mach_info::float_format)
  {
    unimplemented ("load", "binary");

    return true;
  }

  bool
  base_fcn_handle::save_hdf5 (octave_hdf5_id, const char *, bool)
  {
    unimplemented ("save", "hdf5");

    return true;
  }

  bool
  base_fcn_handle::load_hdf5 (octave_hdf5_id&, octave_hdf5_id&, octave_hdf5_id&)
  {
    unimplemented ("load", "hdf5");

    return true;
  }

  void base_fcn_handle::warn_load (const char *file_type) const
  {
    std::string obj_type = type ();

    warning_with_id
      ("Octave:load-save-unavailable",
       "%s: loading %s files not available in this version of Octave",
       obj_type.c_str (), file_type);
  }

  void base_fcn_handle::warn_save (const char *file_type) const
  {
    std::string obj_type = type ();

    warning_with_id
      ("Octave:load-save-unavailable",
       "%s: saving %s files not available in this version of Octave",
       obj_type.c_str (), file_type);
  }

  void base_fcn_handle::unimplemented (const char *op, const char *fmt) const
  {
    std::string htype = type ();

    warning ("%s for %s handles with %s format is not implemented",
             op, htype.c_str (), fmt);
  }

  octave_value_list
  invalid_fcn_handle::call (int, const octave_value_list&)
  {
    error ("invalid call to invalid function handle");
  }

  octave_value_list
  internal_fcn_handle::call (int nargout, const octave_value_list& args)
  {
    interpreter& interp = __get_interpreter__ ("internal_fcn_handle::call");

    return interp.feval (m_fcn, args, nargout);
  }

  octave_scalar_map internal_fcn_handle::info (void)
  {
    octave_scalar_map m;

    m.setfield ("function", fcn_name ());
    m.setfield ("type", type ());
    m.setfield ("file", "");

    return m;
  }

  bool is_equal_to (const internal_fcn_handle& fh1,
                    const internal_fcn_handle& fh2)
  {
    if (fh1.m_name == fh2.m_name
        && fh1.m_fcn.is_defined () && fh2.m_fcn.is_defined ())
      return fh1.m_fcn.is_copy_of (fh2.m_fcn);
    else
      return false;
  }

  octave_value_list
  simple_fcn_handle::call (int nargout, const octave_value_list& args)
  {
    // FIXME: if m_name has a '.' in the name, lookup first component.  If
    // it is a classdef meta object, then build TYPE and IDX arguments and
    // make a subsref call using them.

    interpreter& interp = __get_interpreter__ ("simple_fcn_handle::call");

    octave_value fcn_to_call;

    // The following code is similar to part of
    // tree_evaluator::visit_index_expression but simpler because it
    // handles a more restricted case.

    symbol_table& symtab = interp.get_symbol_table ();

    std::size_t pos = m_name.find ('.');

    if (pos != std::string::npos)
      {
        // FIXME: check to see which of these cases actually work in
        // Octave and Matlab.  For the last two, assume handle is
        // created before object is defined as an object.
        //
        // We can have one of
        //
        //   pkg-list . fcn  (args)
        //   pkg-list . cls . meth (args)
        //   class-name . method  (args)
        //   class-name . static-method  (args)
        //   object . method  (args)
        //   object . static-method  (args)

        // Evaluate package elements until we find a function,
        // classdef object, or classdef_meta object that is not a
        // package.  An object may only appear as the first element,
        // then it must be followed directly by a function name.

        std::size_t beg = 0;
        std::size_t end = pos;

        std::vector<std::string> idx_elts;

        while (true)
          {
            end = m_name.find ('.', beg);

            idx_elts.push_back (m_name.substr (beg, end-beg));

            if (end == std::string::npos)
              break;

            beg = end+1;
          }

        std::size_t n_elts = idx_elts.size ();

        bool have_object = false;
        octave_value partial_expr_val;

        // Lazy evaluation.  The first element was not known to be defined
        // as an object in the scope where the handle was created.  See if
        // there is a definition in the current scope.

        partial_expr_val = interp.varval (idx_elts[0]);

        if (partial_expr_val.is_defined ())
          {
            if (! partial_expr_val.is_classdef_object () || n_elts != 2)
              err_invalid_fcn_handle (m_name);

            have_object = true;
          }
        else
          partial_expr_val = symtab.find_function (idx_elts[0], ovl ());

        std::string type;
        std::list<octave_value_list> arg_list;

        for (std::size_t i = 1; i < n_elts; i++)
          {
            if (partial_expr_val.is_package ())
              {
                if (have_object)
                  err_invalid_fcn_handle (m_name);

                type = ".";
                arg_list.push_back (ovl (idx_elts[i]));

                try
                  {
                    // Silently ignore extra output values.

                    octave_value_list tmp_list
                      = partial_expr_val.subsref (type, arg_list, 0);

                    partial_expr_val
                      = tmp_list.length () ? tmp_list(0) : octave_value ();

                    if (partial_expr_val.is_cs_list ())
                      err_invalid_fcn_handle (m_name);

                    arg_list.clear ();
                  }
                catch (const index_exception&)
                  {
                    err_invalid_fcn_handle (m_name);
                  }
              }
            else if (have_object || partial_expr_val.is_classdef_meta ())
              {
                // Object or class name must be the next to the last
                // element (it was the previous one, so if this is the
                // final element, it should be a classdef method,
                // but we'll let the classdef or classdef_meta subsref
                // function sort that out.

                if (i != n_elts-1)
                  err_invalid_fcn_handle (m_name);

                type = ".(";
                arg_list.push_back (ovl (idx_elts[i]));
                arg_list.push_back (args);

                return partial_expr_val.subsref (type, arg_list, nargout);
              }
            else
              err_invalid_fcn_handle (m_name);
          }

        // If we get here, we must have a function to call.

        if (! partial_expr_val.is_function ())
          err_invalid_fcn_handle (m_name);

        fcn_to_call = partial_expr_val;
      }
    else
      {
        // No "." in the name.

        // Perform function lookup given current arguments.  We'll need
        // to do this regardless of whether a function was found when
        // the handle was created.

        octave_value ov_fcn = symtab.find_function (m_name, args);

        if (m_fcn.is_defined ())
          {
            // A simple function was found when the handle was created.
            // Use that unless we find a class method to override it.

            fcn_to_call = m_fcn;

            if (ov_fcn.is_defined ())
              {
                octave_function *fcn = ov_fcn.function_value ();

                std::string dispatch_class = fcn->dispatch_class ();

                if (fcn->is_class_method ())
                  {
                    // Function found through lookup is a class method
                    // so use it instead of the simple one found when
                    // the handle was created.

                    fcn_to_call = ov_fcn;
                  }
              }
          }
        else
          {
            // There was no simple function found when the handle was
            // created so use the one found here (if any).

            fcn_to_call = ov_fcn;
          }
      }

    if (! fcn_to_call.is_defined ())
      err_invalid_fcn_handle (m_name);

    return interp.feval (fcn_to_call, args, nargout);
  }

  octave_function * simple_fcn_handle::function_value (bool)
  {
    // FIXME: Shouldn't the lookup rules here match those used in the
    // call method?

    if (m_fcn.is_defined ())
      return m_fcn.function_value ();

    symbol_table& symtab
      = __get_symbol_table__ ("simple_fcn_handle::function_value");

    // FIXME: is caching the correct thing to do?
    // Cache this value so that the pointer will be valid as long as the
    // function handle object is valid.

    m_fcn = symtab.find_function (m_name, octave_value_list ());

    return m_fcn.is_defined () ? m_fcn.function_value () : nullptr;
  }

  octave_user_function * simple_fcn_handle::user_function_value (bool)
  {
    // FIXME: Shouldn't the lookup rules here match those used in the
    // call method?

    if (m_fcn.is_defined ())
      return m_fcn.user_function_value ();

    symbol_table& symtab
      = __get_symbol_table__ ("simple_fcn_handle::user_function_value");

    // FIXME: is caching the correct thing to do?
    // Cache this value so that the pointer will be valid as long as the
    // function handle object is valid.

    m_fcn = symtab.find_user_function (m_name);

    return m_fcn.is_defined () ? m_fcn.user_function_value () : nullptr;
  }

  octave_value simple_fcn_handle::fcn_val (void)
  {
    if (m_fcn.is_defined ())
      return m_fcn;

    symbol_table& symtab
      = __get_symbol_table__ ("simple_fcn_handle::user_function_value");

    // FIXME: is caching the correct thing to do?
    // Cache this value so that the pointer will be valid as long as the
    // function handle object is valid.

    m_fcn = symtab.find_user_function (m_name);

    return m_fcn;
  }

  octave_scalar_map simple_fcn_handle::info (void)
  {
    octave_scalar_map m;

    m.setfield ("function", fcn_name ());
    m.setfield ("type", type ());
    // When is FILE defined for simple function handles?
    m.setfield ("file", file ());

    return m;
  }

  bool simple_fcn_handle::save_ascii (std::ostream& os)
  {
    os << "# octaveroot: " << config::octave_exec_home () << "\n";

    std::string fnm = file ();
    if (! fnm.empty ())
      os << "# path: " << fnm << "\n";

    os << "# subtype: " << type () << "\n";

    os << m_name << "\n";

    return true;
  }

  bool simple_fcn_handle::load_ascii (std::istream& is)
  {
    // FIXME: If m_file is not empty, try to load the file and define
    // the function?  Is it an error if that fails?  Or should this job
    // always be deferred until the handle is used?

    return is.good ();
  }

  bool simple_fcn_handle::save_binary (std::ostream& os, bool)
  {
    std::ostringstream nmbuf;

    // When is FILE defined for simple function handles?
    std::string fnm;

    nmbuf << m_name << "@<simple>\n" << config::octave_exec_home ()
          << "\n" << fnm;

    std::string buf_str = nmbuf.str ();
    int32_t tmp = buf_str.length ();
    os.write (reinterpret_cast<char *> (&tmp), 4);
    os.write (buf_str.c_str (), buf_str.length ());

    return true;
  }

  bool simple_fcn_handle::load_binary (std::istream& is, bool,
                                       mach_info::float_format)
  {
    return is.good ();
  }

  bool simple_fcn_handle::save_hdf5 (octave_hdf5_id loc_id, const char *name,
                                     bool)
  {
#if defined (HAVE_HDF5)

    bool retval = true;

    octave_hdf5_id group_hid = -1;
#if defined (HAVE_HDF5_18)
    group_hid = H5Gcreate (loc_id, name, octave_H5P_DEFAULT, octave_H5P_DEFAULT,
                           octave_H5P_DEFAULT);
#else
    group_hid = H5Gcreate (loc_id, name, 0);
#endif
    if (group_hid < 0)
      return false;

    octave_hdf5_id space_hid, data_hid, type_hid;
    space_hid = data_hid = type_hid = -1;

    // attach the type of the variable
    type_hid = H5Tcopy (H5T_C_S1);
    H5Tset_size (type_hid, m_name.length () + 1);
    if (type_hid < 0)
      {
        H5Gclose (group_hid);
        return false;
      }

    OCTAVE_LOCAL_BUFFER (hsize_t, hdims, 2);
    hdims[0] = 0;
    hdims[1] = 0;
    space_hid = H5Screate_simple (0, hdims, nullptr);
    if (space_hid < 0)
      {
        H5Tclose (type_hid);
        H5Gclose (group_hid);
        return false;
      }
#if defined (HAVE_HDF5_18)
    data_hid = H5Dcreate (group_hid, "nm",  type_hid, space_hid,
                          octave_H5P_DEFAULT, octave_H5P_DEFAULT,
                          octave_H5P_DEFAULT);
#else
    data_hid = H5Dcreate (group_hid, "nm",  type_hid, space_hid,
                          octave_H5P_DEFAULT);
#endif
    if (data_hid < 0
        || H5Dwrite (data_hid, type_hid, octave_H5S_ALL, octave_H5S_ALL,
                     octave_H5P_DEFAULT, m_name.c_str ()) < 0)
      {
        H5Sclose (space_hid);
        H5Tclose (type_hid);
        H5Gclose (group_hid);
        return false;
      }
    H5Dclose (data_hid);

    std::string octaveroot = config::octave_exec_home ();

    // When is FILE defined for simple fucntion handles?
    std::string fpath;

    H5Sclose (space_hid);
    hdims[0] = 1;
    hdims[1] = octaveroot.length ();
    space_hid = H5Screate_simple (0, hdims, nullptr);
    if (space_hid < 0)
      {
        H5Tclose (type_hid);
        H5Gclose (group_hid);
        return false;
      }

    H5Tclose (type_hid);
    type_hid = H5Tcopy (H5T_C_S1);
    H5Tset_size (type_hid, octaveroot.length () + 1);
    octave_hdf5_id a_id;
#if defined (HAVE_HDF5_18)
    a_id = H5Acreate (group_hid, "OCTAVEROOT", type_hid, space_hid,
                      octave_H5P_DEFAULT, octave_H5P_DEFAULT);
#else
    a_id = H5Acreate (group_hid, "OCTAVEROOT", type_hid, space_hid,
                      octave_H5P_DEFAULT);
#endif

    if (a_id >= 0)
      {
        retval = (H5Awrite (a_id, type_hid, octaveroot.c_str ()) >= 0);

        H5Aclose (a_id);
      }
    else
      {
        H5Sclose (space_hid);
        H5Tclose (type_hid);
        H5Gclose (group_hid);
        return false;
      }

    H5Sclose (space_hid);
    hdims[0] = 1;
    hdims[1] = fpath.length ();
    space_hid = H5Screate_simple (0, hdims, nullptr);
    if (space_hid < 0)
      {
        H5Tclose (type_hid);
        H5Gclose (group_hid);
        return false;
      }

    H5Tclose (type_hid);
    type_hid = H5Tcopy (H5T_C_S1);
    H5Tset_size (type_hid, fpath.length () + 1);

#if defined (HAVE_HDF5_18)
    a_id = H5Acreate (group_hid, "FILE", type_hid, space_hid,
                      octave_H5P_DEFAULT, octave_H5P_DEFAULT);
#else
    a_id = H5Acreate (group_hid, "FILE", type_hid, space_hid, octave_H5P_DEFAULT);
#endif

    if (a_id >= 0)
      {
        retval = (H5Awrite (a_id, type_hid, fpath.c_str ()) >= 0);

        H5Aclose (a_id);
      }
    else
      retval = false;

    H5Sclose (space_hid);
    H5Tclose (type_hid);
    H5Gclose (group_hid);

    return retval;

#else

    octave_unused_parameter (loc_id);
    octave_unused_parameter (name);

    warn_save ("hdf5");

    return false;

#endif
  }

  bool simple_fcn_handle::load_hdf5 (octave_hdf5_id& group_hid,
                                     octave_hdf5_id& space_hid,
                                     octave_hdf5_id& type_hid)
  {
#if defined (HAVE_HDF5)

    unimplemented ("load", "hdf5");

    octave_unused_parameter (group_hid);
    octave_unused_parameter (space_hid);
    octave_unused_parameter (type_hid);

    return true;

#else

    octave_unused_parameter (group_hid);
    octave_unused_parameter (space_hid);
    octave_unused_parameter (type_hid);

    return false;

#endif
  }

  void simple_fcn_handle::print_raw (std::ostream& os, bool pr_as_read_syntax,
                                     int current_print_indent_level) const
  {
    octave_print_internal (os, '@' + m_name, pr_as_read_syntax,
                           current_print_indent_level);
  }

  bool is_equal_to (const simple_fcn_handle& fh1, const simple_fcn_handle& fh2)
  {
    if (fh1.m_name == fh2.m_name)
      {
        if (fh1.m_fcn.is_defined () && fh2.m_fcn.is_defined ())
          return fh1.m_fcn.is_copy_of (fh2.m_fcn);

        if (fh1.m_fcn.is_undefined () && fh2.m_fcn.is_undefined ())
          return true;
      }

    return false;
  }

  scoped_fcn_handle::scoped_fcn_handle (const octave_value& fcn,
                                        const std::string& name,
                                        const std::list<std::string>& parentage)
    : base_fcn_handle (name), m_fcn (fcn), m_parentage (parentage)
  {
    // FIXME: should it be an error if FCN is undefined?

    if (m_fcn.is_defined ())
      {
        octave_function *oct_fcn = m_fcn.function_value ();

        if (oct_fcn)
          m_file = oct_fcn->fcn_file_name ();
      }

    m_parentage.push_front (name);
  }

  octave_value_list
  scoped_fcn_handle::call (int nargout, const octave_value_list& args)
  {
    // FIXME: we aren't really using the scope yet.  Hmm.

    interpreter& interp = __get_interpreter__ ("simple_fcn_handle::call");

    if (! m_fcn.is_defined ())
      {
        // Try to find it?

        find_function ();
      }

    if (! m_fcn.is_defined ())
      err_invalid_fcn_handle (m_name);

    return interp.feval (m_fcn, args, nargout);
  }

  octave_scalar_map scoped_fcn_handle::info (void)
  {
    octave_scalar_map m;

    m.setfield ("function", fcn_name ());
    m.setfield ("type", type ());
    m.setfield ("file", file ());

    m.setfield ("parentage", Cell (m_parentage));

    return m;
  }

  bool scoped_fcn_handle::save_ascii (std::ostream& os)
  {
    os << "# octaveroot: " << config::octave_exec_home () << "\n";

    std::string fnm = file ();
    if (! fnm.empty ())
      os << "# path: " << fnm << "\n";

    os << "# subtype: " << type () << "\n";

    os << m_name << "\n";

    octave_value tmp = Cell (m_parentage);
    tmp.save_ascii (os);

    return os.good ();
  }

  bool scoped_fcn_handle::load_ascii (std::istream& is)
  {
    octave_cell ov_cell;
    ov_cell.load_ascii (is);

    if (ov_cell.iscellstr ())
      {
        Array<std::string> cellstr_val = ov_cell.cellstr_value ();

        for (octave_idx_type i = 0; i < cellstr_val.numel (); i++)
          m_parentage.push_back (cellstr_val(i));
      }

    return is.good ();
  }

  bool scoped_fcn_handle::save_binary (std::ostream& os, bool save_as_floats)
  {
    std::ostringstream nmbuf;

    std::string fnm = file ();

    nmbuf << m_name << "@<scopedfunction>\n" << config::octave_exec_home ()
          << "\n" << fnm;

    std::string buf_str = nmbuf.str ();
    int32_t len = buf_str.length ();
    os.write (reinterpret_cast<char *> (&len), 4);
    os.write (buf_str.c_str (), buf_str.length ());

    octave_value tmp = Cell (m_parentage);
    tmp.save_binary (os, save_as_floats);

    return os.good ();
  }

  bool scoped_fcn_handle::load_binary (std::istream& is, bool swap,
                                       mach_info::float_format fmt)
  {
    octave_cell ov_cell;
    ov_cell.load_binary (is, swap, fmt);

    if (ov_cell.iscellstr ())
      {
        Array<std::string> cellstr_val = ov_cell.cellstr_value ();

        for (octave_idx_type i = 0; i < cellstr_val.numel (); i++)
          m_parentage.push_back (cellstr_val(i));
      }

    return is.good ();
  }

  bool scoped_fcn_handle::save_hdf5 (octave_hdf5_id loc_id, const char *name,
                                     bool)
  {
#if defined (HAVE_HDF5)

    unimplemented ("save", "hdf5");

    // FIXME: save parentage.

    octave_unused_parameter (loc_id);
    octave_unused_parameter (name);

    return true;

#else

    octave_unused_parameter (loc_id);
    octave_unused_parameter (name);

    warn_save ("hdf5");

    return false;

#endif
  }

  bool scoped_fcn_handle::load_hdf5 (octave_hdf5_id& group_hid,
                                     octave_hdf5_id& space_hid,
                                     octave_hdf5_id& type_hid)
  {
#if defined (HAVE_HDF5)

    unimplemented ("load", "hdf5");

    // FIXME: load parentage.

    octave_unused_parameter (group_hid);
    octave_unused_parameter (space_hid);
    octave_unused_parameter (type_hid);

    return true;

#else

    octave_unused_parameter (group_hid);
    octave_unused_parameter (space_hid);
    octave_unused_parameter (type_hid);

    return false;

#endif
  }

  void scoped_fcn_handle::print_raw (std::ostream& os,
                                     bool pr_as_read_syntax,
                                     int current_print_indent_level) const
  {
    octave_print_internal (os, '@' + m_name, pr_as_read_syntax,
                           current_print_indent_level);
  }

 bool is_equal_to (const scoped_fcn_handle& fh1, const scoped_fcn_handle& fh2)
  {
    if (fh1.m_name == fh2.m_name
        && fh2.m_parentage == fh2.m_parentage
        && fh1.m_fcn.is_defined () && fh2.m_fcn.is_defined ())
      return fh1.m_fcn.is_copy_of (fh2.m_fcn);
    else
      return false;
  }

  void scoped_fcn_handle::find_function (void)
  {
    // Since a scoped function is not visible by itself, try to load the
    // file named in m_file then find and define the scoped function.
    // It is not an error if this fails.  We can report later that the
    // handle is invalid.

    symbol_table& symtab
      = __get_symbol_table__ ("scoped_fcn_handle::find_function");

    if (m_parentage.size () == 1)
      {
        std::string dir_name = sys::file_ops::dirname (m_file);

        std::size_t pos = dir_name.find_last_of (sys::file_ops::dir_sep_chars ());

        if (pos != std::string::npos)
          dir_name = dir_name.substr (0, pos);
        else if (dir_name == "private")
          dir_name = ".";

        std::string fcn_name = m_parentage.front ();

        // FIXME: Does dir_name need to be in the load path for this to work?

        m_fcn = symtab.find_private_function (dir_name, m_name);

        // FIXME: Verify that it is a private function?
      }
    else
      {
        std::string primary_parent_name = m_parentage.back ();

        octave_value ov_parent_fcn
          = symtab.find_user_function (primary_parent_name);

        if (ov_parent_fcn.is_defined ())
          {
            octave_user_function *fcn = ov_parent_fcn.user_function_value ();

            if (fcn)
              {
                std::string file_name = fcn->fcn_file_name ();

                std::string oct_home = config::octave_exec_home ();

                if (file_name.substr (0, oct_home.size ()) == oct_home)
                  file_name = file_name.substr (oct_home.size ());

                octave_value subfun = fcn->find_subfunction (m_name);

                if (subfun.is_defined ())
                  m_fcn = subfun;
              }
          }
      }
  }

  octave_scalar_map base_nested_fcn_handle::info (void)
  {
    octave_scalar_map m;

    m.setfield ("function", fcn_name ());
    m.setfield ("type", type ());
    m.setfield ("file", "");
    m.setfield ("workspace", workspace ());

    return m;
  }

  // FIXME: For save, we need a way to save the (possibly shared)
  // workspace.  For load, we need a way to load and link to the
  // (possibly shared) workspace that was saved.
  //
  // Since a nested function is not visible by itself, do we need to try
  // to load the file named in m_file then find and define the function?
  // Is it an error if that fails?  Or should this job always be
  // deferred until the handle is used?

  bool base_nested_fcn_handle::save_ascii (std::ostream& os)
  {
    unimplemented ("save", "text");

    octave_unused_parameter (os);

    return true;
  }

  bool base_nested_fcn_handle::load_ascii (std::istream& is)
  {
    unimplemented ("load", "text");

    octave_unused_parameter (is);

    return true;
  }

  bool base_nested_fcn_handle::save_binary (std::ostream& os,
                                            bool save_as_floats)
  {
    unimplemented ("save", "binary");

    octave_unused_parameter (os);
    octave_unused_parameter (save_as_floats);

    return true;
  }

  bool base_nested_fcn_handle::load_binary (std::istream& is, bool swap,
                                            mach_info::float_format fmt)
  {
    unimplemented ("load", "binary");

    octave_unused_parameter (is);
    octave_unused_parameter (swap);
    octave_unused_parameter (fmt);

    return true;
  }

  bool base_nested_fcn_handle::save_hdf5 (octave_hdf5_id loc_id,
                                          const char *name, bool)
  {
#if defined (HAVE_HDF5)

    unimplemented ("save", "hdf5");

    octave_unused_parameter (loc_id);
    octave_unused_parameter (name);

    return true;

#else

    octave_unused_parameter (loc_id);
    octave_unused_parameter (name);

    warn_save ("hdf5");

    return false;

#endif
  }

  bool base_nested_fcn_handle::load_hdf5 (octave_hdf5_id& group_hid,
                                          octave_hdf5_id& space_hid,
                                          octave_hdf5_id& type_hid)
  {
#if defined (HAVE_HDF5)

    unimplemented ("load", "hdf5");

    octave_unused_parameter (group_hid);
    octave_unused_parameter (space_hid);
    octave_unused_parameter (type_hid);

    return true;

#else

    octave_unused_parameter (group_hid);
    octave_unused_parameter (space_hid);
    octave_unused_parameter (type_hid);

    return false;

#endif
  }

  void base_nested_fcn_handle::print_raw (std::ostream& os,
                                          bool pr_as_read_syntax,
                                          int current_print_indent_level) const
  {
    octave_print_internal (os, '@' + m_name, pr_as_read_syntax,
                           current_print_indent_level);
  }

  octave_value nested_fcn_handle::make_weak_nested_handle (void) const
  {
    return octave_value (new octave_fcn_handle
                         (new weak_nested_fcn_handle (*this)));
  }

  octave_value_list
  nested_fcn_handle::call (int nargout, const octave_value_list& args)
  {
    tree_evaluator& tw = __get_evaluator__ ("nested_fcn_handle::call");

    octave_user_function *oct_usr_fcn = m_fcn.user_function_value ();

    tw.push_stack_frame (oct_usr_fcn, m_stack_context);

    unwind_action act ([&tw] () { tw.pop_stack_frame (); });

    return oct_usr_fcn->execute (tw, nargout, args);
  }

  octave_value nested_fcn_handle::workspace (void) const
  {
    return m_stack_context->workspace ();
  }

  bool is_equal_to (const nested_fcn_handle& fh1, const nested_fcn_handle& fh2)
  {
    if (fh1.m_name == fh2.m_name
        && fh1.m_fcn.is_defined () && fh2.m_fcn.is_defined ())
      return fh1.m_fcn.is_copy_of (fh2.m_fcn);
    else
      return false;
  }

  octave_value_list
  weak_nested_fcn_handle::call (int nargout, const octave_value_list& args)
  {
    tree_evaluator& tw = __get_evaluator__ ("weak_nested_fcn_handle::call");

    octave_user_function *oct_usr_fcn = m_fcn.user_function_value ();

    std::shared_ptr<stack_frame> frames = m_stack_context.lock ();

    tw.push_stack_frame (oct_usr_fcn, frames);

    unwind_action act ([&tw] () { tw.pop_stack_frame (); });

    return oct_usr_fcn->execute (tw, nargout, args);
  }

  octave_value weak_nested_fcn_handle::workspace (void) const
  {
    std::shared_ptr<stack_frame> frames = m_stack_context.lock ();

    return frames ? frames->workspace () : octave_value ();
  }

  bool is_equal_to (const weak_nested_fcn_handle& fh1,
                    const weak_nested_fcn_handle& fh2)
  {
    if (fh1.m_name == fh2.m_name
        && fh1.m_fcn.is_defined () && fh2.m_fcn.is_defined ())
      return fh1.m_fcn.is_copy_of (fh2.m_fcn);
    else
      return false;
  }

  class_simple_fcn_handle::class_simple_fcn_handle (const std::string& class_nm,
                                                    const std::string& meth_nm)
    : base_fcn_handle (meth_nm), m_obj (), m_fcn (),
      m_dispatch_class (class_nm)
  { }

  class_simple_fcn_handle::class_simple_fcn_handle (const octave_value& fcn,
                                                    const std::string& class_nm,
                                                    const std::string& meth_nm)
    : base_fcn_handle (meth_nm), m_obj (), m_fcn (fcn),
      m_dispatch_class (class_nm)
  { }

  class_simple_fcn_handle::class_simple_fcn_handle (const octave_value& obj,
                                                    const octave_value& fcn,
                                                    const std::string& class_nm,
                                                    const std::string& meth_nm)
    : base_fcn_handle (meth_nm), m_obj (obj), m_fcn (fcn),
      m_dispatch_class (class_nm)
  { }

  octave_value_list
  class_simple_fcn_handle::call (int nargout, const octave_value_list& args)
  {
    interpreter& interp = __get_interpreter__ ("class_simple_fcn_handle::call");

    if (m_obj.is_defined ())
      {
        octave_value_list tmp_args = args;
        tmp_args.prepend (m_obj);

        return interp.feval (m_fcn, tmp_args, nargout);
      }

    // FIXME: is this the best approach?  Should we be saving current
    // dispatch class and restoring that value instead of
    // unconditionally setting it to "" when we return from this
    // function?

    tree_evaluator& tw = interp.get_evaluator ();

    unwind_action act ([&tw] () { tw.set_dispatch_class (""); });

    tw.set_dispatch_class (m_dispatch_class);

    if (m_fcn.is_defined ())
      return interp.feval (m_fcn, args, nargout);

    return interp.feval (fcn_name (), args, nargout);
  }

  octave_scalar_map class_simple_fcn_handle::info (void)
  {
    octave_scalar_map m;

    m.setfield ("function", fcn_name ());
    m.setfield ("type", type ());
    m.setfield ("file", "");
    m.setfield ("class", dispatch_class ());

    return m;
  }

  // FIXME: Since a class method is not visible by itself, do we need to
  // try to load the file named in m_file then find and define the
  // function?  Is it an error if that fails?  Or should this job always
  // be deferred until the handle is used?

  bool class_simple_fcn_handle::save_ascii (std::ostream& os)
  {
    unimplemented ("save", "text");

    octave_unused_parameter (os);

    return true;
  }

  bool class_simple_fcn_handle::load_ascii (std::istream& is)
  {
    unimplemented ("load", "text");

    octave_unused_parameter (is);

    return true;
  }

  bool class_simple_fcn_handle::save_binary (std::ostream& os,
                                             bool save_as_floats)
  {
    unimplemented ("save", "binary");

    octave_unused_parameter (os);
    octave_unused_parameter (save_as_floats);

    return true;
  }

  bool class_simple_fcn_handle::load_binary (std::istream& is, bool swap,
                                             mach_info::float_format fmt)
  {
    unimplemented ("load", "binary");

    octave_unused_parameter (is);
    octave_unused_parameter (swap);
    octave_unused_parameter (fmt);

    return true;
  }

  bool class_simple_fcn_handle::save_hdf5 (octave_hdf5_id loc_id,
                                           const char *name, bool)
  {
#if defined (HAVE_HDF5)

    unimplemented ("save", "hdf5");

    octave_unused_parameter (loc_id);
    octave_unused_parameter (name);

    return true;

#else

    octave_unused_parameter (loc_id);
    octave_unused_parameter (name);

    warn_save ("hdf5");

    return false;

#endif
  }

  bool class_simple_fcn_handle::load_hdf5 (octave_hdf5_id& group_hid,
                                           octave_hdf5_id& space_hid,
                                           octave_hdf5_id& type_hid)
  {
#if defined (HAVE_HDF5)

    unimplemented ("load", "hdf5");

    octave_unused_parameter (group_hid);
    octave_unused_parameter (space_hid);
    octave_unused_parameter (type_hid);

    return true;

#else

    octave_unused_parameter (group_hid);
    octave_unused_parameter (space_hid);
    octave_unused_parameter (type_hid);

    return false;

#endif
  }

  void class_simple_fcn_handle::print_raw (std::ostream& os,
                                           bool pr_as_read_syntax,
                                           int current_print_indent_level) const
  {
    octave_print_internal (os, '@' + m_name, pr_as_read_syntax,
                           current_print_indent_level);
  }

  bool is_equal_to (const class_simple_fcn_handle& fh1,
                    const class_simple_fcn_handle& fh2)
  {
    // FIXME: Also need to check object values are equivalent?

    if (fh1.m_name == fh2.m_name
        && fh1.m_fcn.is_defined () && fh2.m_fcn.is_defined ())
      return fh1.m_fcn.is_copy_of (fh2.m_fcn);
    else
      return false;
  }

  const std::string base_anonymous_fcn_handle::anonymous ("@<anonymous>");

  octave_scalar_map base_anonymous_fcn_handle::info (void)
  {
    octave_scalar_map m;

    std::ostringstream buf;
    print_raw (buf, true, 0);
    m.setfield ("function", buf.str ());

    m.setfield ("type", type ());
    m.setfield ("file", "");
    m.setfield ("workspace", workspace ());
    m.setfield ("within_file_path", "");

    return m;
  }

  bool base_anonymous_fcn_handle::save_ascii (std::ostream& os)
  {
    // FIXME: can we ensure that m_fcn is always defined?

    if (m_fcn.is_undefined ())
      return false;

    os << m_name << "\n";

    print_raw (os, true, 0);
    os << "\n";

    std::size_t varlen = m_local_vars.size ();

    if (varlen > 0)
      {
        os << "# length: " << varlen << "\n";

        for (const auto& nm_val : m_local_vars)
          {
            if (! save_text_data (os, nm_val.second, nm_val.first, false, 0))
              return ! os.fail ();
          }
      }

    return true;
  }

  bool base_anonymous_fcn_handle::load_ascii (std::istream& is)
  {
    octave::skip_preceeding_newline (is);

    std::string buf;

    if (is)
      {
        // Get a line of text whitespace characters included, leaving
        // newline in the stream.

        buf = octave::read_until_newline (is, true);
      }

    std::streampos pos = is.tellg ();

    // Set up temporary scope to use for evaluating the text that
    // defines the anonymous function.

    interpreter& interp
      = __get_interpreter__ ("base_anonymous_fcn_handle::load_ascii");

    tree_evaluator& tw = interp.get_evaluator ();

    tw.push_dummy_scope (buf);
    unwind_action_safe restore_scope (&tree_evaluator::pop_scope, &tw);

    octave_idx_type len = 0;

    if (extract_keyword (is, "length", len, true) && len >= 0)
      {
        if (len > 0)
          {
            for (octave_idx_type i = 0; i < len; i++)
              {
                octave_value t2;
                bool dummy;

                std::string name = read_text_data (is, "", dummy, t2, i);

                if (! is)
                  error ("load: failed to load anonymous function handle");

                m_local_vars[name] = t2;
              }
          }
      }
    else
      {
        is.seekg (pos);
        is.clear ();
      }

    if (is)
      return parse (buf);

    return false;
  }

  bool base_anonymous_fcn_handle::save_binary (std::ostream& os,
                                               bool save_as_floats)
  {
    // FIXME: can we ensure that m_fcn is always defined?

    if (m_fcn.is_undefined ())
      return false;

    std::ostringstream nmbuf;

    std::size_t varlen = m_local_vars.size ();

    nmbuf << anonymous;
    if (varlen > 0)
      nmbuf << ' ' << varlen;

    std::string buf_str = nmbuf.str ();
    int32_t tmp = buf_str.length ();
    os.write (reinterpret_cast<char *> (&tmp), 4);
    os.write (buf_str.c_str (), buf_str.length ());

    std::ostringstream buf;
    print_raw (buf, true, 0);
    std::string stmp = buf.str ();
    tmp = stmp.length ();
    os.write (reinterpret_cast<char *> (&tmp), 4);
    os.write (stmp.c_str (), stmp.length ());

    if (varlen > 0)
      {
        for (const auto& nm_val : m_local_vars)
          {
            if (! save_binary_data (os, nm_val.second, nm_val.first,
                                    "", 0, save_as_floats))
              return ! os.fail ();
          }
      }

    return true;
  }

  bool base_anonymous_fcn_handle::load_binary (std::istream& is, bool swap,
                                               mach_info::float_format fmt)
  {
    // Read extra characters in m_name as the number of local variable
    // values in this anonymous function.

    octave_idx_type len = 0;
    std::size_t anl = anonymous.length ();
    if (m_name.length () > anl)
      {
        std::istringstream nm_is (m_name.substr (anl));
        nm_is >> len;

        // Anonymous functons don't have names.  We just used this
        // string as temporary storage to pass the number of local
        // variable values.

        m_name = "";
      }

    int32_t tmp;

    if (! is.read (reinterpret_cast<char *> (&tmp), 4))
      return false;
    if (swap)
      swap_bytes<4> (&tmp);

    OCTAVE_LOCAL_BUFFER (char, ctmp2, tmp+1);
    // is.get (ctmp2, tmp+1, 0); caused is.eof () to be true though
    // effectively not reading over file end
    is.read (ctmp2, tmp);
    ctmp2[tmp] = 0;

    // Set up temporary scope to use for evaluating the text that
    // defines the anonymous function.

    interpreter& interp
      = __get_interpreter__ ("base_anonymous_fcn_handle::load_binary");

    tree_evaluator& tw = interp.get_evaluator ();

    tw.push_dummy_scope (ctmp2);
    unwind_action_safe restore_scope (&tree_evaluator::pop_scope, &tw);

    if (len > 0)
      {
        for (octave_idx_type i = 0; i < len; i++)
          {
            octave_value t2;
            bool dummy;
            std::string doc;

            std::string name
              = read_binary_data (is, swap, fmt, "", dummy, t2, doc);

            if (! is)
              error ("load: failed to load anonymous function handle");

            m_local_vars[name] = t2;
          }
      }

    if (is)
      return parse (ctmp2);

    return false;
  }

  bool base_anonymous_fcn_handle::save_hdf5 (octave_hdf5_id loc_id,
                                             const char *name,
                                             bool save_as_floats)
  {
#if defined (HAVE_HDF5)

    bool retval = true;

    octave_hdf5_id group_hid = -1;
#if defined (HAVE_HDF5_18)
    group_hid = H5Gcreate (loc_id, name, octave_H5P_DEFAULT, octave_H5P_DEFAULT,
                           octave_H5P_DEFAULT);
#else
    group_hid = H5Gcreate (loc_id, name, 0);
#endif
    if (group_hid < 0)
      return false;

    octave_hdf5_id space_hid, data_hid, type_hid;
    space_hid = data_hid = type_hid = -1;

    // attach the type of the variable
    type_hid = H5Tcopy (H5T_C_S1);
    H5Tset_size (type_hid, m_name.length () + 1);
    if (type_hid < 0)
      {
        H5Gclose (group_hid);
        return false;
      }

    OCTAVE_LOCAL_BUFFER (hsize_t, hdims, 2);
    hdims[0] = 0;
    hdims[1] = 0;
    space_hid = H5Screate_simple (0, hdims, nullptr);
    if (space_hid < 0)
      {
        H5Tclose (type_hid);
        H5Gclose (group_hid);
        return false;
      }
#if defined (HAVE_HDF5_18)
    data_hid = H5Dcreate (group_hid, "nm",  type_hid, space_hid,
                          octave_H5P_DEFAULT, octave_H5P_DEFAULT,
                          octave_H5P_DEFAULT);
#else
    data_hid = H5Dcreate (group_hid, "nm",  type_hid, space_hid,
                          octave_H5P_DEFAULT);
#endif
    if (data_hid < 0
        || H5Dwrite (data_hid, type_hid, octave_H5S_ALL, octave_H5S_ALL,
                     octave_H5P_DEFAULT, m_name.c_str ()) < 0)
      {
        H5Sclose (space_hid);
        H5Tclose (type_hid);
        H5Gclose (group_hid);
        return false;
      }
    H5Dclose (data_hid);

    std::ostringstream buf;
    print_raw (buf, true, 0);
    std::string stmp = buf.str ();

    // attach the type of the variable
    H5Tset_size (type_hid, stmp.length () + 1);
    if (type_hid < 0)
      {
        H5Sclose (space_hid);
        H5Gclose (group_hid);
        return false;
      }

#if defined (HAVE_HDF5_18)
    data_hid = H5Dcreate (group_hid, "fcn",  type_hid, space_hid,
                          octave_H5P_DEFAULT, octave_H5P_DEFAULT,
                          octave_H5P_DEFAULT);
#else
    data_hid = H5Dcreate (group_hid, "fcn",  type_hid, space_hid,
                          octave_H5P_DEFAULT);
#endif
    if (data_hid < 0
        || H5Dwrite (data_hid, type_hid, octave_H5S_ALL, octave_H5S_ALL,
                     octave_H5P_DEFAULT, stmp.c_str ()) < 0)
      {
        H5Sclose (space_hid);
        H5Tclose (type_hid);
        H5Gclose (group_hid);
        return false;
      }

    H5Dclose (data_hid);

    std::size_t varlen = m_local_vars.size ();

    if (varlen > 0)
      {
        octave_hdf5_id as_id = H5Screate (H5S_SCALAR);

        if (as_id >= 0)
          {
            octave_hdf5_id a_id;
#if defined (HAVE_HDF5_18)
            a_id = H5Acreate (group_hid, "SYMBOL_TABLE", H5T_NATIVE_IDX, as_id,
                              octave_H5P_DEFAULT, octave_H5P_DEFAULT);

#else
            a_id = H5Acreate (group_hid, "SYMBOL_TABLE", H5T_NATIVE_IDX, as_id,
                              octave_H5P_DEFAULT);
#endif

            if (a_id >= 0)
              {
                retval = (H5Awrite (a_id, H5T_NATIVE_IDX, &varlen) >= 0);

                H5Aclose (a_id);
              }
            else
              retval = false;

            H5Sclose (as_id);
          }
        else
          retval = false;
#if defined (HAVE_HDF5_18)
        data_hid = H5Gcreate (group_hid, "symbol table",
                              octave_H5P_DEFAULT, octave_H5P_DEFAULT, octave_H5P_DEFAULT);
#else
        data_hid = H5Gcreate (group_hid, "symbol table", 0);
#endif
        if (data_hid < 0)
          {
            H5Sclose (space_hid);
            H5Tclose (type_hid);
            H5Gclose (group_hid);
            return false;
          }

        for (const auto& nm_val : m_local_vars)
          {
            if (! add_hdf5_data (data_hid, nm_val.second, nm_val.first,
                                 "", false, save_as_floats))
              break;
          }

        H5Gclose (data_hid);
      }

    H5Sclose (space_hid);
    H5Tclose (type_hid);
    H5Gclose (group_hid);

    return retval;

#else

    octave_unused_parameter (loc_id);
    octave_unused_parameter (name);
    octave_unused_parameter (save_as_floats);

    warn_save ("hdf5");

    return false;

#endif
  }

  bool base_anonymous_fcn_handle::load_hdf5 (octave_hdf5_id& group_hid,
                                             octave_hdf5_id& space_hid,
                                             octave_hdf5_id& type_hid)
  {
#if defined (HAVE_HDF5)

    bool success = true;

#if defined (HAVE_HDF5_18)
    octave_hdf5_id data_hid = H5Dopen (group_hid, "fcn", octave_H5P_DEFAULT);
#else
    octave_hdf5_id data_hid = H5Dopen (group_hid, "fcn");
#endif

    if (data_hid < 0)
      {
        H5Sclose (space_hid);
        H5Tclose (type_hid);
        H5Gclose (group_hid);
        return false;
      }

    H5Tclose (type_hid);
    type_hid = H5Dget_type (data_hid);
    octave_hdf5_id type_class_hid = H5Tget_class (type_hid);

    if (type_class_hid != H5T_STRING)
      {
        H5Sclose (space_hid);
        H5Tclose (type_hid);
        H5Dclose (data_hid);
        H5Gclose (group_hid);
        return false;
      }

    H5Sclose (space_hid);
    space_hid = H5Dget_space (data_hid);
    hsize_t rank = H5Sget_simple_extent_ndims (space_hid);

    if (rank != 0)
      {
        H5Sclose (space_hid);
        H5Tclose (type_hid);
        H5Dclose (data_hid);
        H5Gclose (group_hid);
        return false;
      }

    int slen = H5Tget_size (type_hid);
    if (slen < 0)
      {
        H5Sclose (space_hid);
        H5Tclose (type_hid);
        H5Dclose (data_hid);
        H5Gclose (group_hid);
        return false;
      }

    OCTAVE_LOCAL_BUFFER (char, fcn_tmp, slen);

    // create datatype for (null-terminated) string to read into:
    octave_hdf5_id st_id = H5Tcopy (H5T_C_S1);
    H5Tset_size (st_id, slen);

    if (H5Dread (data_hid, st_id, octave_H5S_ALL, octave_H5S_ALL,
                 octave_H5P_DEFAULT, fcn_tmp)
        < 0)
      {
        H5Tclose (st_id);
        H5Sclose (space_hid);
        H5Tclose (type_hid);
        H5Dclose (data_hid);
        H5Gclose (group_hid);
        return false;
      }
    H5Tclose (st_id);
    H5Dclose (data_hid);

    octave_idx_type len = 0;

    // we have to pull some shenanigans here to make sure
    // HDF5 doesn't print out all sorts of error messages if we
    // call H5Aopen for a non-existing attribute

    H5E_auto_t err_func;
    void *err_func_data;

    // turn off error reporting temporarily, but save the error
    // reporting function:
#if defined (HAVE_HDF5_18)
    H5Eget_auto (octave_H5E_DEFAULT, &err_func, &err_func_data);
    H5Eset_auto (octave_H5E_DEFAULT, nullptr, nullptr);
#else
    H5Eget_auto (&err_func, &err_func_data);
    H5Eset_auto (nullptr, nullptr);
#endif

    octave_hdf5_id attr_id = H5Aopen_name (group_hid, "SYMBOL_TABLE");

    if (attr_id >= 0)
      {
        if (H5Aread (attr_id, H5T_NATIVE_IDX, &len) < 0)
          success = false;

        H5Aclose (attr_id);
      }

    // restore error reporting:
#if defined (HAVE_HDF5_18)
    H5Eset_auto (octave_H5E_DEFAULT, err_func, err_func_data);
#else
    H5Eset_auto (err_func, err_func_data);
#endif

    // Set up temporary scope to use for evaluating the text that
    // defines the anonymous function.

    interpreter& interp
      = __get_interpreter__ ("base_anonymous_fcn_handle::load_hdf5");

    tree_evaluator& tw = interp.get_evaluator ();

    tw.push_dummy_scope (fcn_tmp);
    unwind_action_safe restore_scope (&tree_evaluator::pop_scope, &tw);

    if (len > 0 && success)
      {
        hsize_t num_obj = 0;
#if defined (HAVE_HDF5_18)
        data_hid = H5Gopen (group_hid, "symbol table", octave_H5P_DEFAULT);
#else
        data_hid = H5Gopen (group_hid, "symbol table");
#endif
        H5Gget_num_objs (data_hid, &num_obj);
        H5Gclose (data_hid);

        if (num_obj != static_cast<hsize_t> (len))
          error ("load: failed to load anonymous function handle");

        hdf5_callback_data dsub;
        int current_item = 0;
        for (octave_idx_type i = 0; i < len; i++)
          {
            if (hdf5_h5g_iterate (group_hid, "symbol table", &current_item,
                                  &dsub) <= 0)
              error ("load: failed to load anonymous function handle");

            m_local_vars[dsub.name] = dsub.tc;
          }
      }

    if (success)
      return parse (fcn_tmp);

    return false;

#else

    octave_unused_parameter (group_hid);
    octave_unused_parameter (space_hid);
    octave_unused_parameter (type_hid);

    return false;

#endif
  }

  void base_anonymous_fcn_handle::print_raw (std::ostream& os, bool, int) const
  {
    tree_print_code tpc (os);

    octave_user_function *f = m_fcn.user_function_value ();

    if (! f)
      error ("invalid anonymous function handle");

    os << "@";

    // The parameter list should always be valid for anonymous
    // functions, so we should always call accept for it, and it will
    // print the parens for us.

    tree_parameter_list *p = f->parameter_list ();

    if (p)
      p->accept (tpc);

    os << " ";

    tree_statement_list *b = f->body ();

    assert (b->length () == 1);

    tree_statement *s = b->front ();

    if (! s)
      error ("invalid anonymous function handle");

    assert (s->is_expression ());

    tree_expression *e = s->expression ();

    if (! e)
      error ("invalid anonymous function handle");

    tpc.print_fcn_handle_body (e);
  }

  bool base_anonymous_fcn_handle::parse (const std::string& fcn_text)
  {
    // FIXME: If evaluation of the string gives us an anonymous function
    // handle object, then why extract the function and create a new
    // anonymous function object?  Why not just attach the workspace
    // values to the object returned by eval_string?  This code is also is
    // duplicated in read_mat5_binary_element in ls-mat5.cc.

    interpreter& interp
      = __get_interpreter__ ("base_anonymous_fcn_handle::parse");

    // Set up temporary scope to use for evaluating the text that defines
    // the anonymous function so that we don't pick up values of random
    // variables that might be in the current scope.

    tree_evaluator& tw = interp.get_evaluator ();
    tw.push_dummy_scope ("read_mat5_binary_element");

    unwind_action act ([&tw] () { tw.pop_scope (); });

    int parse_status;
    octave_value anonymous_fcn_hdl
      = interp.eval_string (fcn_text, true, parse_status);

    if (parse_status != 0)
      return false;

    octave_fcn_handle *fh = anonymous_fcn_hdl.fcn_handle_value ();

    if (! fh)
      return false;

    m_fcn = fh->fcn_val ();

    octave_user_function *uf = m_fcn.user_function_value (true);

    if (uf)
      {
        symbol_scope uf_scope = uf->scope ();

        if (uf_scope)
          uf_scope.cache_name (m_name);
      }

    return true;
  }

  anonymous_fcn_handle::anonymous_fcn_handle (const octave_value& fcn,
                                              const stack_frame::local_vars_map& local_vars,
                                              const std::shared_ptr<stack_frame>& stack_context)
    : base_anonymous_fcn_handle (fcn, local_vars),
      m_stack_context (stack_context)
  { }

  octave_value anonymous_fcn_handle::make_weak_anonymous_handle (void) const
  {
    return octave_value (new octave_fcn_handle
                         (new weak_anonymous_fcn_handle (*this)));
  }

  octave_value_list
  anonymous_fcn_handle::call (int nargout, const octave_value_list& args)
  {
    tree_evaluator& tw = __get_evaluator__ ("anonymous_fcn_handle::call");

    octave_user_function *oct_usr_fcn = m_fcn.user_function_value ();

    tw.push_stack_frame (oct_usr_fcn, m_local_vars, m_stack_context);

    unwind_action act ([&tw] () { tw.pop_stack_frame (); });

    return oct_usr_fcn->execute (tw, nargout, args);
  }

  octave_value anonymous_fcn_handle::workspace (void) const
  {
    octave_scalar_map local_vars_map;

    for (const auto& nm_val : m_local_vars)
      local_vars_map.assign (nm_val.first, nm_val.second);

    // FIXME: it would be more convenient if stack_frame::workspace
    // returned a Cell object directly instead of a Cell in an
    // octave_value object.

    Cell cell_frames;

    if (m_stack_context)
      {
        octave_value ov_frames = m_stack_context->workspace ();
        cell_frames = ov_frames.cell_value ();
      }

    octave_idx_type num_frames = cell_frames.numel ();
    // FIXME: It seems there should be a simple way to concatenate cells...
    Cell retval = Cell (num_frames+1, 1);
    retval(0) = m_local_vars;
    for (octave_idx_type i = 0; i < num_frames; i++)
      retval(i+1) = cell_frames(i);

    return retval;
  }

  bool is_equal_to (const anonymous_fcn_handle& fh1,
                    const anonymous_fcn_handle& fh2)
  {
    if (fh1.m_fcn.is_defined () && fh2.m_fcn.is_defined ())
      return fh1.m_fcn.is_copy_of (fh2.m_fcn);
    else
      return false;
  }

  octave_value_list
  weak_anonymous_fcn_handle::call (int nargout, const octave_value_list& args)
  {
    tree_evaluator& tw = __get_evaluator__ ("anonymous_fcn_handle::call");

    octave_user_function *oct_usr_fcn = m_fcn.user_function_value ();

    std::shared_ptr<stack_frame> frames = m_stack_context.lock ();

    tw.push_stack_frame (oct_usr_fcn, m_local_vars, frames);

    unwind_action act ([&tw] () { tw.pop_stack_frame (); });

    return oct_usr_fcn->execute (tw, nargout, args);
  }

  octave_value weak_anonymous_fcn_handle::workspace (void) const
  {
    octave_scalar_map local_vars_map;

    for (const auto& nm_val : m_local_vars)
      local_vars_map.assign (nm_val.first, nm_val.second);

    // FIXME: it would be more convenient if stack_frame::workspace
    // returned a Cell object directly instead of a Cell in an
    // octave_value object.

    std::shared_ptr<stack_frame> frames = m_stack_context.lock ();

    Cell cell_frames;

    if (frames)
      {
        octave_value ov_frames = frames->workspace ();
        cell_frames = ov_frames.cell_value ();
      }

    octave_idx_type num_frames = cell_frames.numel ();

    // FIXME: It seems there should be a simple way to concatenate
    // cells...
    Cell retval = Cell (num_frames+1, 1);
    retval(0) = m_local_vars;
    for (octave_idx_type i = 0; i < num_frames; i++)
      retval(i+1) = cell_frames(i);

    return retval;
  }

  bool is_equal_to (const weak_anonymous_fcn_handle& fh1,
                    const weak_anonymous_fcn_handle& fh2)
  {
    if (fh1.m_name == fh2.m_name
        && fh1.m_fcn.is_defined () && fh2.m_fcn.is_defined ())
      return fh1.m_fcn.is_copy_of (fh2.m_fcn);
    else
      return false;
  }

OCTAVE_NAMESPACE_END

octave_fcn_handle::octave_fcn_handle (void)
  : octave_base_value (), m_rep (new octave::invalid_fcn_handle ())
{ }

octave_fcn_handle::octave_fcn_handle (const octave_value& fcn)
  : octave_base_value (), m_rep (new octave::internal_fcn_handle (fcn))
{ }

octave_fcn_handle::octave_fcn_handle (const std::string& name)
  : octave_base_value (), m_rep (new octave::simple_fcn_handle (name))
{ }

octave_fcn_handle::octave_fcn_handle (const octave_value& fcn,
                                      const std::string& name)
  : octave_base_value (), m_rep (new octave::simple_fcn_handle (fcn, name))
{ }

octave_fcn_handle::octave_fcn_handle (const std::string& class_nm,
                                      const std::string& meth_nm)
  : octave_base_value (),
    m_rep (new octave::class_simple_fcn_handle (class_nm, meth_nm))
{ }

octave_fcn_handle::octave_fcn_handle (const octave_value& fcn,
                                      const std::string& class_nm,
                                      const std::string& meth_nm)
  : octave_base_value (),
    m_rep (new octave::class_simple_fcn_handle (fcn, class_nm, meth_nm))
{ }

octave_fcn_handle::octave_fcn_handle (const octave_value& obj,
                                      const octave_value& fcn,
                                      const std::string& class_nm,
                                      const std::string& meth_nm)
  : octave_base_value (),
    m_rep (new octave::class_simple_fcn_handle (obj, fcn, class_nm, meth_nm))
{ }

octave_fcn_handle::octave_fcn_handle (const octave_value& fcn,
                                      const std::string& name,
                                      const std::list<std::string>& parentage)
  : octave_base_value (),
    m_rep (new octave::scoped_fcn_handle (fcn, name, parentage))
{ }

octave_fcn_handle::octave_fcn_handle (const octave_value& fcn,
                                      const std::string& name,
                                      const std::shared_ptr<octave::stack_frame>& stack_context)
  : octave_base_value (),
    m_rep (new octave::nested_fcn_handle (fcn, name, stack_context))
{ }

octave_fcn_handle::octave_fcn_handle (const octave_value& fcn,
                                      const octave::stack_frame::local_vars_map& local_vars,
                                      const std::shared_ptr<octave::stack_frame>& stack_context)
  : octave_base_value (),
    m_rep (new octave::anonymous_fcn_handle (fcn, local_vars, stack_context))
{ }

octave_fcn_handle::octave_fcn_handle (octave::base_fcn_handle *rep)
  : octave_base_value (), m_rep (rep)
{ }

octave_fcn_handle::octave_fcn_handle (const octave_fcn_handle& fh)
  : octave_base_value (fh)
{
  m_rep.reset (fh.m_rep->clone ());
}

dim_vector
octave_fcn_handle::dims (void) const
{
  static dim_vector dv (1, 1);
  return dv;
}

bool
octave_fcn_handle::save_ascii (std::ostream& os)
{
  return m_rep->save_ascii (os);
}

bool
octave_fcn_handle::load_ascii (std::istream& is)
{
  std::shared_ptr<octave::base_fcn_handle> new_rep;

  // Read enough to detect type then create new rep object and dispatch
  // to finish loading object.

  std::streampos pos = is.tellg ();

  std::string octaveroot = extract_keyword (is, "octaveroot", true);
  if (octaveroot.empty ())
    {
      is.seekg (pos);
      is.clear ();
    }

  pos = is.tellg ();

  std::string fpath = extract_keyword (is, "path", true);
  if (fpath.empty ())
    {
      is.seekg (pos);
      is.clear ();
    }

  if (! (octaveroot.empty () || fpath.empty ()))
    {
      std::size_t len = octaveroot.size ();
      if (octaveroot == fpath.substr (0, len))
        fpath = octave::config::octave_exec_home () + fpath.substr (len);
    }

  pos = is.tellg ();

  std::string subtype = extract_keyword (is, "subtype", true);
  if (subtype.empty ())
    {
      is.seekg (pos);
      is.clear ();

      // We have a legacy file that can contain either an anonymous
      // function or a simple function handle.

      std::string name;
      is >> name;

      if (name == anonymous)
        new_rep.reset (new octave::anonymous_fcn_handle ());
      else
        new_rep.reset (new octave::simple_fcn_handle (name, fpath, octaveroot));
    }
  else
    {
      // Load individual function handle types.

      if (subtype == "simple")
        {
          std::string name;
          is >> name;

          new_rep.reset (new octave::simple_fcn_handle (name, fpath, octaveroot));
        }
      else if (subtype == "scopedfunction")
        {
          std::string name;
          is >> name;

          new_rep.reset (new octave::scoped_fcn_handle (name, fpath, octaveroot));
        }
      else if (subtype == "anonymous")
        new_rep.reset (new octave::anonymous_fcn_handle ());
      else if (subtype == "nested")
        {
          std::string name;
          is >> name;

          new_rep.reset (new octave::nested_fcn_handle (name, fpath, octaveroot));
        }
      else if (subtype == "classsimple")
        {
          std::string name;
          is >> name;

          new_rep.reset (new octave::class_simple_fcn_handle (name, fpath, octaveroot));
        }
    }

  if (! new_rep)
    return false;

  if (! new_rep->load_ascii (is))
    return false;

  m_rep = new_rep;

  return true;
}

bool
octave_fcn_handle::save_binary (std::ostream& os, bool save_as_floats)
{
  return m_rep->save_binary (os, save_as_floats);
}

bool
octave_fcn_handle::load_binary (std::istream& is, bool swap,
                                octave::mach_info::float_format fmt)
{
  // Read enough to detect type then create new rep object and dispatch
  // to finish loading object.

  int32_t tmp;
  if (! is.read (reinterpret_cast<char *> (&tmp), 4))
    return false;
  if (swap)
    swap_bytes<4> (&tmp);

  OCTAVE_LOCAL_BUFFER (char, ctmp1, tmp+1);
  // is.get (ctmp1, tmp+1, 0); caused is.eof () to be true though
  // effectively not reading over file end
  is.read (ctmp1, tmp);
  ctmp1[tmp] = 0;
  std::string name (ctmp1);

  if (! is)
    return false;

  std::shared_ptr<octave::base_fcn_handle> new_rep;

  std::size_t anl = anonymous.length ();

  if (name.length () >= anl && name.substr (0, anl) == anonymous)
    {
      // Even with extra info stored in the function name, anonymous
      // functions look the same.  Note that NAME here may have the
      // number of local variables appended.  We decode that inside the
      // load_binary function.

      new_rep.reset (new octave::anonymous_fcn_handle (name));
    }
  else
    {
      // Unpack extra info stored with the function name and load
      // individual function handle types.
      // FIXME: is there a better way?

      std::string octaveroot;
      std::string fpath;
      std::string subtype = "simple";

      if (name.find_first_of ('\n') != std::string::npos)
        {
          std::size_t pos1 = name.find_first_of ('\n');
          std::size_t pos2 = name.find_first_of ('\n', pos1 + 1);
          octaveroot = name.substr (pos1 + 1, pos2 - pos1 - 1);
          fpath = name.substr (pos2 + 1);
          name = name.substr (0, pos1);
        }

      std::size_t pos1 = name.find ('@');
      if (pos1 != std::string::npos)
        {
          if (name[pos1+1] == '<')
            {
              std::size_t pos2 = name.find ('>', pos1 + 2);

              if (pos2 != std::string::npos)
                subtype = name.substr (pos1 + 2, pos2 - pos1 - 2);
            }

          name = name.substr (0, pos1);
        }

      // Anonymous should have been handled above so it is not in the
      // following list.

      if (subtype == "simple")
        new_rep.reset (new octave::simple_fcn_handle (name, fpath, octaveroot));
      else if (subtype == "scopedfunction")
        new_rep.reset (new octave::scoped_fcn_handle (name, fpath, octaveroot));
      else if (subtype == "nested")
        new_rep.reset (new octave::nested_fcn_handle (name, fpath, octaveroot));
      else if (subtype == "classsimple")
        new_rep.reset (new octave::class_simple_fcn_handle (name, fpath, octaveroot));
    }

  if (! new_rep)
    return false;

  if (! new_rep->load_binary (is, swap, fmt))
    return false;

  m_rep = new_rep;

  return true;
}

bool
octave_fcn_handle::save_hdf5 (octave_hdf5_id loc_id, const char *name,
                              bool save_as_floats)
{
  return m_rep->save_hdf5 (loc_id, name, save_as_floats);
}

bool
octave_fcn_handle::load_hdf5 (octave_hdf5_id loc_id, const char *name_arg)
{
#if defined (HAVE_HDF5)

#if defined (HAVE_HDF5_18)
  octave_hdf5_id group_hid = H5Gopen (loc_id, name_arg, octave_H5P_DEFAULT);
#else
  octave_hdf5_id group_hid = H5Gopen (loc_id, name_arg);
#endif
  if (group_hid < 0)
    return false;

#if defined (HAVE_HDF5_18)
  octave_hdf5_id data_hid = H5Dopen (group_hid, "nm", octave_H5P_DEFAULT);
#else
  octave_hdf5_id data_hid = H5Dopen (group_hid, "nm");
#endif

  if (data_hid < 0)
    {
      H5Gclose (group_hid);
      return false;
    }

  octave_hdf5_id type_hid = H5Dget_type (data_hid);
  octave_hdf5_id type_class_hid = H5Tget_class (type_hid);

  if (type_class_hid != H5T_STRING)
    {
      H5Tclose (type_hid);
      H5Dclose (data_hid);
      H5Gclose (group_hid);
      return false;
    }

  octave_hdf5_id space_hid = H5Dget_space (data_hid);
  hsize_t rank = H5Sget_simple_extent_ndims (space_hid);

  if (rank != 0)
    {
      H5Sclose (space_hid);
      H5Tclose (type_hid);
      H5Dclose (data_hid);
      H5Gclose (group_hid);
      return false;
    }

  int slen = H5Tget_size (type_hid);
  if (slen < 0)
    {
      H5Sclose (space_hid);
      H5Tclose (type_hid);
      H5Dclose (data_hid);
      H5Gclose (group_hid);
      return false;
    }

  OCTAVE_LOCAL_BUFFER (char, nm_tmp, slen);

  // create datatype for (null-terminated) string to read into:
  octave_hdf5_id st_id = H5Tcopy (H5T_C_S1);
  H5Tset_size (st_id, slen);

  if (H5Dread (data_hid, st_id, octave_H5S_ALL, octave_H5S_ALL,
               octave_H5P_DEFAULT, nm_tmp)
      < 0)
    {
      H5Tclose (st_id);
      H5Sclose (space_hid);
      H5Tclose (type_hid);
      H5Dclose (data_hid);
      H5Gclose (group_hid);
      return false;
    }
  H5Tclose (st_id);
  H5Dclose (data_hid);

  std::string name (nm_tmp);

  std::shared_ptr<octave::base_fcn_handle> new_rep;

  if (name == anonymous)
    {
      // Even with extra info stored in the function name, anonymous
      // functions look the same.

      new_rep.reset (new octave::anonymous_fcn_handle ());
    }
  else
    {
      // Unpack extra info stored with the function name and load
      // individual function handle types.
      // FIXME: is there a better way?

      std::string octaveroot;
      std::string fpath;
      std::string subtype = "simple";

      if (name.find_first_of ('\n') != std::string::npos)
        {
          std::size_t pos1 = name.find_first_of ('\n');
          std::size_t pos2 = name.find_first_of ('\n', pos1 + 1);
          octaveroot = name.substr (pos1 + 1, pos2 - pos1 - 1);
          fpath = name.substr (pos2 + 1);
          name = name.substr (0, pos1);
        }

      std::size_t pos1 = name.find ('@');
      if (pos1 != std::string::npos)
        {
          if (name[pos1+1] == '<')
            {
              std::size_t pos2 = name.find ('>', pos1 + 2);

              if (pos2 != std::string::npos)
                subtype = name.substr (pos1 + 2, pos2 - pos1 - 2);
            }

          name = name.substr (0, pos1);
        }

      // Anonymous should have been handled above so it is not in the
      // following list.

      if (subtype == "simple")
        new_rep.reset (new octave::simple_fcn_handle (name, fpath, octaveroot));
      else if (subtype == "scopedfunction")
        new_rep.reset (new octave::scoped_fcn_handle (name, fpath, octaveroot));
      else if (subtype == "nested")
        new_rep.reset (new octave::nested_fcn_handle (name, fpath, octaveroot));
      else if (subtype == "classsimple")
        new_rep.reset (new octave::class_simple_fcn_handle (name, fpath, octaveroot));
    }

  bool status = false;

  if (new_rep && new_rep->load_hdf5 (group_hid, space_hid, type_hid))
    {
      m_rep = new_rep;
      status = true;
    }

  // FIXME: manage these with an unwind_action object?

  H5Tclose (type_hid);
  H5Sclose (space_hid);
  H5Gclose (group_hid);

  return status;

#else

  octave_unused_parameter (loc_id);
  octave_unused_parameter (name_arg);

  warn_load ("hdf5");

  return false;

#endif
}

/*
%!test <*33857>
%! a = 2;
%! f = @(x) a + x;
%! g = @(x) 2 * x;
%! hm = @version;
%! hdld = @svd;
%! hbi = @log2;
%! f2 = f;
%! g2 = g;
%! hm2 = hm;
%! hdld2 = hdld;
%! hbi2 = hbi;
%! modes = {"-text", "-binary"};
%! if (isfield (__octave_config_info__, "HAVE_HDF5")
%!     && __octave_config_info__ ("HAVE_HDF5"))
%!   modes(end+1) = "-hdf5";
%! endif
%! for i = 1:numel (modes)
%!   mode = modes{i};
%!   nm = tempname ();
%!   unwind_protect
%!     f2 (1);
%!     save (mode, nm, "f2", "g2", "hm2", "hdld2", "hbi2");
%!     clear f2 g2 hm2 hdld2 hbi2
%!     load (nm);
%!     assert (f (2), f2 (2));
%!     assert (g (2), g2 (2));
%!     assert (g (3), g2 (3));
%!     unlink (nm);
%!     save (mode, nm, "f2", "g2", "hm2", "hdld2", "hbi2");
%!   unwind_protect_cleanup
%!     unlink (nm);
%!   end_unwind_protect
%! endfor
*/

/*
%!function fcn_handle_save_recurse (n, mode, nm, f2, g2, hm2, hdld2, hbi2)
%!  if (n == 0)
%!    save (mode, nm, "f2", "g2", "hm2", "hdld2", "hbi2");
%!  else
%!    fcn_handle_save_recurse (n - 1, mode, nm, f2, g2, hm2, hdld2, hbi2);
%!  endif
%!endfunction
%!function [f2, g2, hm2, hdld2, hbi2] = fcn_handle_load_recurse (n, nm)
%!  if (n == 0)
%!    load (nm);
%!  else
%!    [f2, g2, hm2, hdld2, hbi2] = fcn_handle_load_recurse (n - 1, nm);
%!  endif
%!endfunction

%!test <*35876>
%! a = 2;
%! f = @(x) a + x;
%! g = @(x) 2 * x;
%! hm = @version;
%! hdld = @svd;
%! hbi = @log2;
%! f2 = f;
%! g2 = g;
%! hm2 = hm;
%! hdld2 = hdld;
%! hbi2 = hbi;
%! modes = {"-text", "-binary"};
%! if (isfield (__octave_config_info__, "HAVE_HDF5")
%!     && __octave_config_info__ ("HAVE_HDF5"))
%!   modes(end+1) = "-hdf5";
%! endif
%! for i = 1:numel (modes)
%!   mode = modes{i};
%!   nm = tempname ();
%!   unwind_protect
%!     fcn_handle_save_recurse (2, mode, nm, f2, g2, hm2, hdld2, hbi2);
%!     clear f2 g2 hm2 hdld2 hbi2
%!     [f2, f2, hm2, hdld2, hbi2] = fcn_handle_load_recurse (2, nm);
%!     load (nm);
%!     assert (f (2), f2 (2));
%!     assert (g (2), g2 (2));
%!     assert (g (3), g2 (3));
%!     unlink (nm);
%!     fcn_handle_save_recurse (2, mode, nm, f2, g2, hm2, hdld2, hbi2);
%!   unwind_protect_cleanup
%!     unlink (nm);
%!   end_unwind_protect
%! endfor
*/

void
octave_fcn_handle::print (std::ostream& os, bool pr_as_read_syntax)
{
  print_raw (os, pr_as_read_syntax);
  newline (os);
}

void
octave_fcn_handle::print_raw (std::ostream& os, bool pr_as_read_syntax) const
{
  m_rep->print_raw (os, pr_as_read_syntax, current_print_indent_level ());
}

bool
is_equal_to (const octave_fcn_handle& fh1, const octave_fcn_handle& fh2)
{
  // FIXME: Maybe there is a better way?  Possibly by using typeid or
  // typeindex?

  // Don't include invalid_fcn_handle in the list of types to compare.
  // Consider them to be like NaN values so comparisons between any two
  // invalid handles are always false.

  if (fh1.is_internal () && fh2.is_internal ())
    return is_equal_to (*dynamic_cast<octave::internal_fcn_handle *> (fh1.get_rep ()),
                        *dynamic_cast<octave::internal_fcn_handle *> (fh2.get_rep ()));
  else if (fh1.is_simple () && fh2.is_simple ())
    return is_equal_to (*dynamic_cast<octave::simple_fcn_handle *> (fh1.get_rep ()),
                        *dynamic_cast<octave::simple_fcn_handle *> (fh2.get_rep ()));
  else if (fh1.is_scoped () && fh2.is_scoped ())
    return is_equal_to (*dynamic_cast<octave::scoped_fcn_handle *> (fh1.get_rep ()),
                        *dynamic_cast<octave::scoped_fcn_handle *> (fh2.get_rep ()));
  else if (fh1.is_nested () && fh2.is_nested ())
    return is_equal_to (*dynamic_cast<octave::nested_fcn_handle *> (fh1.get_rep ()),
                        *dynamic_cast<octave::nested_fcn_handle *> (fh2.get_rep ()));
  else if (fh1.is_class_simple () && fh2.is_class_simple ())
    return is_equal_to (*dynamic_cast<octave::class_simple_fcn_handle *> (fh1.get_rep ()),
                        *dynamic_cast<octave::class_simple_fcn_handle *> (fh2.get_rep ()));
  else if (fh1.is_anonymous () && fh2.is_anonymous ())
    return is_equal_to (*dynamic_cast<octave::anonymous_fcn_handle *> (fh1.get_rep ()),
                        *dynamic_cast<octave::anonymous_fcn_handle *> (fh2.get_rep ()));
  else
    return false;
}

OCTAVE_NAMESPACE_BEGIN

  // DEPRECATED in Octave 6.

  octave_value
  make_fcn_handle (interpreter& interp, const std::string& nm)
  {
    tree_evaluator& tw = interp.get_evaluator ();

    return tw.make_fcn_handle (nm);
  }

DEFUN (functions, args, ,
       doc: /* -*- texinfo -*-
@deftypefn {} {@var{s} =} functions (@var{fcn_handle})
Return a structure containing information about the function handle
@var{fcn_handle}.

The structure @var{s} always contains these three fields:

@table @asis
@item function
The function name.  For an anonymous function (no name) this will be the
actual function definition.

@item type
Type of the function.

@table @asis
@item anonymous
The function is anonymous.

@item private
The function is private.

@item overloaded
The function overloads an existing function.

@item simple
The function is a built-in or m-file function.

@item subfunction
The function is a subfunction within an m-file.
@end table

@item nested
The function is nested.

@item file
The m-file that will be called to perform the function.  This field is empty
for anonymous and built-in functions.
@end table

In addition, some function types may return more information in additional
fields.

@strong{Warning:} @code{functions} is provided for debugging purposes only.
Its behavior may change in the future and programs should not depend on any
particular output format.

@seealso{func2str, str2func}
@end deftypefn */)
{
  if (args.length () != 1)
    print_usage ();

  octave_fcn_handle *fh = args(0).xfcn_handle_value ("functions: FCN_HANDLE argument must be a function handle object");

  return ovl (fh->info ());
}

DEFUN (func2str, args, ,
       doc: /* -*- texinfo -*-
@deftypefn {} {} func2str (@var{fcn_handle})
Return a string containing the name of the function referenced by the
function handle @var{fcn_handle}.
@seealso{str2func, functions}
@end deftypefn */)
{
  if (args.length () != 1)
    print_usage ();

  octave_fcn_handle *fh = args(0).xfcn_handle_value ("func2str: FCN_HANDLE argument must be a function handle object");

  if (! fh)
    error ("func2str: FCN_HANDLE must be a valid function handle");

  octave_value retval;

  std::string fh_nm = fh->fcn_name ();

  if (fh->is_anonymous ())
    {
      std::ostringstream buf;

      fh->print_raw (buf);

      retval = buf.str ();
    }
  else
    retval = fh_nm;

  return retval;
}

DEFMETHOD (str2func, interp, args, ,
           doc: /* -*- texinfo -*-
@deftypefn {} {} str2func (@var{fcn_name})
Return a function handle constructed from the string @var{fcn_name}.

Previous versions of Octave accepted an optional second argument,
@qcode{"global"}, that caused str2func to ignore locally visible
functions.  This option is no longer supported.
@seealso{func2str, functions}
@end deftypefn */)
{
  int nargin = args.length ();

  if (nargin < 1 || nargin > 2)
    print_usage ();

  std::string nm
    = args(0).xstring_value ("str2func: FCN_NAME must be a string");

  if (nm.empty ())
    error ("str2func: invalid function name");

  if (nm[0] == '@')
    {
      // Unlike the anonymous_fcn_handle::parse method, don't set up
      // temporary scope to use for evaluating the text that defines
      // the anonymous function.  Here we want
      //
      //   str2fun ("@(args) expr")
      //
      // to behave the same as if
      //
      //   @(args) expr
      //
      // were evaluated in the current scope.

      int parse_status;
      octave_value afh = interp.eval_string (nm, true, parse_status);

      if (parse_status == 0)
        return afh;
    }
  else
    {
      if (nargin == 2)
        warning_with_id ("Octave:str2func-global-argument",
                         "str2func: second argument ignored");

      tree_evaluator& tw = interp.get_evaluator ();

      return tw.make_fcn_handle (nm);
    }

  return ovl ();
}

/*
%!test
%! f = str2func ("<");
%! assert (class (f), "function_handle");
%! assert (func2str (f), "lt");
%! assert (f (1, 2), true);
%! assert (f (2, 1), false);

%!test
%! f = str2func ("@(x) sin (x)");
%! assert (func2str (f), "@(x) sin (x)");
%! assert (f (0:3), sin (0:3));

%!error <FCN_NAME must be a string> str2func ({"sin"})
*/

/*
%!function y = __testrecursionfunc (f, x, n)
%!  if (nargin < 3)
%!    n = 0;
%!  endif
%!  if (n > 2)
%!    y = f (x);
%!  else
%!    n++;
%!    y = __testrecursionfunc (@(x) f (2*x), x, n);
%!  endif
%!endfunction
%!
%!assert (__testrecursionfunc (@(x) x, 1), 8)
*/

DEFUN (is_function_handle, args, ,
       doc: /* -*- texinfo -*-
@deftypefn {} {} is_function_handle (@var{x})
Return true if @var{x} is a function handle.
@seealso{isa, typeinfo, class, functions}
@end deftypefn */)
{
  if (args.length () != 1)
    print_usage ();

  return ovl (args(0).is_function_handle ());
}

/*
%!shared fh
%! fh = @(x) x;

%!assert (is_function_handle (fh))
%!assert (! is_function_handle ({fh}))
%!assert (! is_function_handle (1))

%!error is_function_handle ()
%!error is_function_handle (1, 2)
*/

/*
%!test
%! f = @(t) eval ('2*t');
%! assert (f (21), 42);
*/

/*
%!test <*58389>
%! s = "x";
%! a.(s) = [e, pi];
%! f = @(x) a.(s)(x);
%! assert (f(1), e);
%! assert (f(2), pi);
%! assert (f([2,1]), [pi, e]);
*/

/*
%!function r = __f (g, i)
%!  r = g(i);
%!endfunction
%!test
%! x = [1,2;3,4];
%! assert (__f (@(i) x(:,i), 1), [1;3]);
*/

OCTAVE_NAMESPACE_END
